Polycrystalline diamond compact

ABSTRACT

In an embodiment, a method of fabricating a polycrystalline diamond compact is disclosed. The method includes sintering a plurality of diamond particles in the presence of a metal-solvent catalyst to form a polycrystalline diamond body; leaching the polycrystalline diamond body to at least partially remove the metal-solvent catalyst therefrom, thereby forming an at least partially leached polycrystalline diamond body; and subjecting an assembly of the at least partially leached polycrystalline diamond body and a cemented carbide substrate to a high-pressure/high-temperature process at a pressure to infiltrate the at least partially leached polycrystalline diamond body with an infiltrant. The pressure of the high-pressure/high-temperature process is less than that employed in the act of sintering of the plurality of diamond particles.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No. 16/358,281 filed on 19 Mar. 2019, which is a continuation of U.S. application Ser. No. 13/789,099 filed on 7 Mar. 2013 (now U.S. Pat. No. 10,287,822 issued on 14 May 2019), which is a continuation of U.S. application Ser. No. 13/623,764 filed on 20 Sep. 2012 (now U.S. Pat. No. 8,616,306 issued on 31 Dec. 2013), which is a continuation of U.S. patent application Ser. No. 12/690,998 filed on 21 Jan. 2010 (now U.S. Pat. No. 8,297,382 issued on 30 Oct. 2012), which is a continuation-in-part of U.S. patent application Ser. No. 12/244,960 filed on 3 Oct. 2008 (now U.S. Pat. No. 7,866,418 issued on 11 Jan. 2011), the disclosure of each of which is incorporated herein, in its entirety, by this reference.

BACKGROUND

Wear-resistant, superabrasive compacts are utilized in a variety of mechanical applications. For example, polycrystalline diamond compacts (“PDCs”) are used in drilling tools (e.g., cutting elements, gage trimmers, etc.), machining equipment, bearing apparatuses, wire-drawing machinery, and in other mechanical apparatuses.

PDCs have found particular utility as superabrasive cutting elements in rotary drill bits, such as roller cone drill bits and fixed-cutter drill bits. A PDC cutting element typically includes a superabrasive diamond layer commonly referred to as a diamond table. The diamond table may be formed and bonded to a substrate using a high-pressure, high-temperature (“HPHT”) process. The PDC cutting element may also be brazed directly into a preformed pocket, socket, or other receptacle formed in a bit body of a rotary drill bit. The substrate may often be brazed or otherwise joined to an attachment member, such as a cylindrical backing. A rotary drill bit typically includes a number of PDC cutting elements affixed to the bit body. A stud carrying the PDC may also be used as a PDC cutting element when mounted to a bit body of a rotary drill bit by press-fitting, brazing, or otherwise securing the stud into a receptacle formed in the bit body.

Conventional PDCs are normally fabricated by placing a cemented carbide substrate into a container with a volume of diamond particles positioned adjacent to the cemented carbide substrate. A number of such cartridges may be loaded into an HPHT press. The substrates and volume of diamond particles are then processed under HPHT conditions in the presence of a catalyst material that causes the diamond particles to bond to one another to form a matrix of bonded diamond grains defining a polycrystalline diamond (“PCD”) table that is bonded to the substrate. The catalyst material is often a metal-solvent catalyst (e.g., cobalt, nickel, iron, or alloys thereof) that is used for promoting intergrowth of the diamond particles. For example, a constituent of the cemented carbide substrate, such as cobalt from a cobalt-cemented tungsten carbide substrate, liquefies and sweeps from a region adjacent to the volume of diamond particles into interstitial regions between the diamond particles during the HPHT process. The cobalt acts as a catalyst to promote intergrowth between the diamond particles, which results in formation of bonded diamond grains.

Because of different coefficients of thermal expansion and modulus of elasticity between the PCD table and the cemented carbide substrate, residual stresses of varying magnitudes may develop within different regions of the PCD table and the cemented carbide substrate. Such residual stresses may remain in the PCD table and cemented carbide substrate following cooling and release of pressure from the HPHT process. These complex stresses may be concentrated near the PCD table/substrate interface. Residual stresses at the interface between the PCD table and cemented carbide substrate may result in premature failure of the PDC upon cooling or during subsequent use under thermal stresses and applied forces.

In order to help reduce de-bonding of the PCD table from the cemented carbide substrate, some PDC designers have made the interfacial surface of the cemented carbide substrate that bonds to the PCD table significantly nonplanar. For example, various nonplanar substrate interfacial surface configurations have been proposed and/or used, such as a plurality of spaced protrusions, a honeycomb-type protrusion pattern, and a variety of other configurations.

SUMMARY

Embodiments of the invention relate to PCD exhibiting enhanced diamond-to-diamond bonding. In an embodiment, PCD includes a plurality of diamond grains defining a plurality of interstitial regions. A metal-solvent catalyst occupies at least a portion of the plurality of interstitial regions. The plurality of diamond grains and the metal-solvent catalyst collectively may exhibit a coercivity of about 115 Oersteds (“Oe”) or more and a specific magnetic saturation of about 15 Gauss·cm³/grams (“G·cm³/g”) or less.

In an embodiment, PCD includes a plurality of diamond grains defining a plurality of interstitial regions. A metal-solvent catalyst occupies the plurality of interstitial regions. The plurality of diamond grains and the metal-solvent catalyst collectively may exhibit a specific magnetic saturation of about 15 G·cm³/g or less. The plurality of diamond grains and the metal-solvent catalyst define a volume of at least about 0.050 cm³.

In an embodiment, a method of fabricating PCD includes enclosing a plurality of diamond particles that exhibit an average particle size of about 30 μm or less, and a metal-solvent catalyst in a pressure transmitting medium to form a cell assembly. The method further includes subjecting the cell assembly to a temperature of at least about 1000° C. and a pressure in the pressure transmitting medium of at least about 7.5 GPa to form the PCD.

In an embodiment, a PDC includes a PCD table bonded to a substrate. At least a portion of the PCD table may comprise any of the PCD embodiments disclosed herein. In an embodiment, the substrate includes an interfacial surface that is bonded to the polycrystalline diamond table and exhibits a substantially planar topography. According to an embodiment, the interfacial surface may include a plurality of protrusions, and a ratio of a surface area of the interfacial surface in the absence of the plurality of provisions to a surface area of the interfacial surface with the plurality of protrusions is greater than about 0.600.

In an embodiment, a method of fabricating a PDC includes enclosing a combination in a pressure transmitting medium to form a cell assembly. The combination includes a plurality of diamond particles that exhibit an average particle size of about 30 μm or less positioned at least proximate to a substrate having an interfacial surface that is substantially planar. The method further includes subjecting the cell assembly to a temperature of at least about 1000° C. and a pressure in the pressure transmitting medium of at least about 7.5 GPa to form a PCD table adjacent to the substrate.

Further embodiments relate to applications utilizing the disclosed PCD and PDCs in various articles and apparatuses, such as rotary drill bits, bearing apparatuses, wire-drawing dies, machining equipment, and other articles and apparatuses.

Features from any of the disclosed embodiments may be used in combination with one another, without limitation. In addition, other features and advantages of the present disclosure will become apparent to those of ordinary skill in the art through consideration of the following detailed description and the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The drawings illustrate several embodiments of the invention, wherein identical reference numerals refer to identical elements or features in different views or embodiments shown in the drawings.

FIG. 1A is a schematic diagram of an example of a magnetic saturation apparatus configured to magnetize a PCD sample approximately to saturation.

FIG. 1B is a schematic diagram of an example of a magnetic saturation measurement apparatus configured to measure a saturation magnetization of a PCD sample.

FIG. 2 is a schematic diagram of an example of a coercivity measurement apparatus configured to determine coercivity of a PCD sample.

FIG. 3A is a cross-sectional view of an embodiment of a PDC including a PCD table formed from any of the PCD embodiments disclosed herein.

FIG. 3B is a schematic illustration of a method of fabricating the PDC shown in FIG. 3A according to an embodiment.

FIG. 3C is a graph of residual principal stress versus substrate thickness that was measured in a PCD table of a PDC fabricated at a pressure above about 7.5 GPa and a PCD table of a conventionally formed PDC.

FIG. 4A is an exploded isometric view of a PDC comprising a substrate including an interfacial surface exhibiting a selected substantially planar topography according to an embodiment.

FIG. 4B is an assembled cross-sectional view of the PDC shown in FIG. 4A taken along line 4B-4B.

FIG. 5A is cross-sectional view of a PDC comprising a substrate including an interfacial surface exhibiting a selected substantially planar topography according to yet another embodiment.

FIG. 5B is an isometric view of the substrate shown in FIG. 5A.

FIG. 6A is an isometric view of an embodiment of a rotary drill bit that may employ one or more of the disclosed PDC embodiments.

FIG. 6B is a top elevation view of the rotary drill bit shown in FIG. 6A.

FIG. 7 is an isometric cutaway view of an embodiment of a thrust-bearing apparatus that may utilize one or more of the disclosed PDC embodiments.

FIG. 8 is an isometric cutaway view of an embodiment of a radial bearing apparatus that may utilize one or more of the disclosed PDC embodiments.

FIG. 9 is a schematic isometric cutaway view of an embodiment of a subterranean drilling system including the thrust-bearing apparatus shown in FIG. 7.

FIG. 10 is a side cross-sectional view of an embodiment of a wire-drawing die that employs a PDC fabricated in accordance with the principles described herein.

DETAILED DESCRIPTION

Embodiments of the invention relate to PCD that exhibits enhanced diamond-to-diamond bonding. It is currently believed by the inventors that as the sintering pressure employed during the HPHT process used to fabricate such PCD is moved further into the diamond-stable region away from the graphite-diamond equilibrium line, the rate of nucleation and growth of diamond increases. Such increased nucleation and growth of diamond between diamond particles (for a given diamond particle formulation) may result in PCD being formed exhibiting one or more of a relatively lower metal-solvent catalyst content, a higher coercivity, a lower specific magnetic saturation, or a lower specific permeability (i.e., the ratio of specific magnetic saturation to coercivity) than PCD formed at a lower sintering pressure. Embodiments also relate to PDCs having a PCD table comprising such PCD, methods of fabricating such PCD and PDCs, and applications for such PCD and PDCs in rotary drill bits, bearing apparatuses, wire-drawing dies, machining equipment, and other articles and apparatuses.

PCD Embodiments

According to various embodiments, PCD sintered at a pressure of at least about 7.5 GPa may exhibit a coercivity of 115 Oe or more, a high-degree of diamond-to-diamond bonding, a specific magnetic saturation of about 15 G·cm³/g or less, and a metal-solvent catalyst content of about 7.5 weight % (“wt %”) or less. The PCD includes a plurality of diamond grains directly bonded together via diamond-to-diamond bonding (e.g., sp³ bonding) to define a plurality of interstitial regions. At least a portion of the interstitial regions or, in some embodiments, substantially all of the interstitial regions may be occupied by a metal-solvent catalyst, such as iron, nickel, cobalt, or alloys of any of the foregoing metals. For example, the metal-solvent catalyst may be a cobalt-based material including at least 50 wt % cobalt, such as a cobalt alloy.

The diamond grains may exhibit an average grain size of about 50 μm or less, such as about 30 μm or less or about 20 μm or less. For example, the average grain size of the diamond grains may be about 10 μm to about 18 μm and, in some embodiments, about 15 μm to about 18 μm. In some embodiments, the average grain size of the diamond grains may be about 10 μm or less, such as about 2 μm to about 5 μm or submicron. The diamond grain size distribution of the diamond grains may exhibit a single mode, or may be a bimodal or greater grain size distribution.

The metal-solvent catalyst that occupies the interstitial regions may be present in the PCD in an amount of about 7.5 wt % or less. In some embodiments, the metal-solvent catalyst may be present in the PCD in an amount of about 3 wt % to about 7.5 wt %, such as about 3 wt % to about 6 wt %. In other embodiments, the metal-solvent catalyst content may be present in the PCD in an amount less than about 3 wt %, such as about 1 wt % to about 3 wt % or a residual amount to about 1 wt %. By maintaining the metal-solvent catalyst content below about 7.5 wt %, the PCD may exhibit a desirable level of thermal stability suitable for subterranean drilling applications.

Many physical characteristics of the PCD may be determined by measuring certain magnetic properties of the PCD because the metal-solvent catalyst may be ferromagnetic. The amount of the metal-solvent catalyst present in the PCD may be correlated with the measured specific magnetic saturation of the PCD. A relatively larger specific magnetic saturation indicates relatively more metal-solvent catalyst in the PCD.

The mean free path between neighboring diamond grains of the PCD may be correlated with the measured coercivity of the PCD. A relatively large coercivity indicates a relatively smaller mean free path. The mean free path is representative of the average distance between neighboring diamond grains of the PCD, and thus may be indicative of the extent of diamond-to-diamond bonding in the PCD. A relatively smaller mean free path, in well-sintered PCD, may indicate relatively more diamond-to-diamond bonding.

As merely one example, ASTM B886-03 (2008) provides a suitable standard for measuring the specific magnetic saturation and ASTM B887-03 (2008) e1 provides a suitable standard for measuring the coercivity of the PCD. Although both ASTM B886-03 (2008) and ASTM B887-03 (2008) e1 are directed to standards for measuring magnetic properties of cemented carbide materials, either standard may be used to determine the magnetic properties of PCD. A KOERZIMAT CS 1.096 instrument (commercially available from Foerster Instruments of Pittsburgh, Pa.) is one suitable instrument that may be used to measure the specific magnetic saturation and the coercivity of the PCD.

Generally, as the sintering pressure that is used to form the PCD increases, the coercivity may increase and the magnetic saturation may decrease. The PCD defined collectively by the bonded diamond grains and the metal-solvent catalyst may exhibit a coercivity of about 115 Oe or more and a metal-solvent catalyst content of less than about 7.5 wt % as indicated by a specific magnetic saturation of about 15 G·cm³/g or less. In a more detailed embodiment, the coercivity of the PCD may be about 115 Oe to about 250 Oe and the specific magnetic saturation of the PCD may be greater than 0 G·cm³/g to about 15 G·cm³/g. In an even more detailed embodiment, the coercivity of the PCD may be about 115 Oe to about 175 Oe and the specific magnetic saturation of the PCD may be about 5 G·cm³/g to about 15 G·cm³/g. In yet an even more detailed embodiment, the coercivity of the PCD may be about 155 Oe to about 175 Oe and the specific magnetic saturation of the PCD may be about 10 G·cm³/g to about 15 G·cm³/g. The specific permeability (i.e., the ratio of specific magnetic saturation to coercivity) of the PCD may be about 0.10 G·cm³/g·Oe or less, such as about 0.060 G·cm³/g·Oe to about 0.090 G·cm³/g·Oe. Despite the average grain size of the bonded diamond grains being less than about 30 μm in some embodiments, the metal-solvent catalyst content in the PCD may be less than about 7.5 wt % resulting in a desirable thermal stability.

In one embodiment, diamond particles having an average particle size of about 18 μm to about 20 μm are positioned adjacent to a cobalt-cemented tungsten carbide substrate and subjected to an HPHT process at a temperature of about 1390° C. to about 1430° C. and a pressure of about 7.8 GPa to about 8.5 GPa. The PCD so-formed as a PCD table bonded to the substrate may exhibit a coercivity of about 155 Oe to about 175 Oe, a specific magnetic saturation of about 10 G·cm³/g to about 15 G·cm³/g, and a cobalt content of about 5 wt % to about 7.5 wt %.

In one or more embodiments, a specific magnetic saturation constant for the metal-solvent catalyst in the PCD may be about 185 G·cm³/g to about 215 G·cm³/g. For example, the specific magnetic saturation constant for the metal-solvent catalyst in the PCD may be about 195 G·cm³/g to about 205 G·cm³/g. It is noted that the specific magnetic saturation constant for the metal-solvent catalyst in the PCD may be composition dependent.

Generally, as the sintering pressure is increased above 7.5 GPa, a wear resistance of the PCD so-formed may increase. For example, the G_(ratio) may be at least about 4.0×10⁶, such as about 5.0×10⁶ to about 15.0×10⁶ or, more particularly, about 8.0×10⁶ to about 15.0×10⁶. In some embodiments, the G_(ratio) may be at least about 30.0×10⁶. The G_(ratio) is the ratio of the volume of workpiece cut to the volume of PCD worn away during the cutting process. An example of suitable parameters that may be used to determine a G_(ratio) of the PCD are a depth of cut for the PCD cutting element of about 0.254 mm, a back rake angle for the PCD cutting element of about 20 degrees, an in-feed for the PCD cutting element of about 6.35 mm/rev, a rotary speed of the workpiece to be cut of about 101 rpm, and the workpiece may be made from Bane granite having a 914 mm outer diameter and a 254 mm inner diameter. During the G_(ratio) test, the workpiece is cooled with a coolant, such as water.

In addition to the aforementioned G_(ratio), despite the presence of the metal-solvent catalyst in the PCD, the PCD may exhibit a thermal stability that is close to, substantially the same as, or greater than a partially leached PCD material formed by sintering a substantially similar diamond particle formulation at a lower sintering pressure (e.g., up to about 5.5 GPa) and in which the metal-solvent catalyst (e.g., cobalt) is leached therefrom to a depth of about 60 μm to about 100 μm from a working surface thereof. The thermal stability of the PCD may be evaluated by measuring the distance cut in a workpiece prior to catastrophic failure, without using coolant, in a vertical lathe test (e.g., vertical turret lathe or a vertical boring mill). An example of suitable parameters that may be used to determine thermal stability of the PCD are a depth of cut for the PCD cutting element of about 1.27 mm, a back rake angle for the PCD cutting element of about 20 degrees, an in-feed for the PCD cutting element of about 1.524 mm/rev, a cutting speed of the workpiece to be cut of about 1.78 m/sec, and the workpiece may be made from Bane granite having a 914 mm outer diameter and a 254 mm inner diameter. In an embodiment, the distance cut in a workpiece prior to catastrophic failure as measured in the above-described vertical lathe test may be at least about 1300 m, such as about 1300 m to about 3950 m.

PCD formed by sintering diamond particles having the same diamond particle size distribution as a PCD embodiment of the invention, but sintered at a pressure of, for example, up to about 5.5 GPa and at temperatures in which diamond is stable may exhibit a coercivity of about 100 Oe or less and/or a specific magnetic saturation of about 16 G·cm³/g or more. Thus, in one or more embodiments of the invention, PCD exhibits a metal-solvent catalyst content of less than 7.5 wt % and a greater amount of diamond-to-diamond bonding between diamond grains than that of a PCD sintered at a lower pressure, but with the same precursor diamond particle size distribution and catalyst.

It is currently believed by the inventors that forming the PCD by sintering diamond particles at a pressure of at least about 7.5 GPa may promote nucleation and growth of diamond between the diamond particles being sintered so that the volume of the interstitial regions of the PCD so-formed is decreased compared to the volume of interstitial regions if the same diamond particle distribution was sintered at a pressure of, for example, up to about 5.5 GPa and at temperatures where diamond is stable. For example, the diamond may nucleate and grow from carbon provided by dissolved carbon in metal-solvent catalyst (e.g., liquefied cobalt) infiltrating into the diamond particles being sintered, partially graphitized diamond particles, carbon from a substrate, carbon from another source (e.g., graphite particles and/or fullerenes mixed with the diamond particles), or combinations of the foregoing. This nucleation and growth of diamond in combination with the sintering pressure of at least about 7.5 GPa may contribute to the PCD so-formed having a metal-solvent catalyst content of less than about 7.5 wt %.

FIGS. 1A, 1B, and 2 schematically illustrate the manner in which the specific magnetic saturation and the coercivity of the PCD may be determined using an apparatus, such as the KOERZIMAT CS 1.096 instrument. FIG. 1A is a schematic diagram of an example of a magnetic saturation apparatus 100 configured to magnetize a PCD sample to saturation. The magnetic saturation apparatus 100 includes a saturation magnet 102 of sufficient strength to magnetize a PCD sample 104 to saturation. The saturation magnet 102 may be a permanent magnet or an electromagnet. In the illustrated embodiment, the saturation magnet 102 is a permanent magnet that defines an air gap 106, and the PCD sample 104 may be positioned on a sample holder 108 within the air gap 106. When the PCD sample 104 is lightweight, it may be secured to the sample holder 108 using, for example, double-sided tape or other adhesive so that the PCD sample 104 does not move responsive to the magnetic field from the saturation magnet 102 and the PCD sample 104 is magnetized at least approximately to saturation.

Referring to the schematic diagram of FIG. 1B, after magnetizing the PCD sample 104 at least approximately to saturation using the magnetic saturation apparatus 100, a magnetic saturation of the PCD sample 104 may be measured using a magnetic saturation measurement apparatus 120. The magnetic saturation measurement apparatus 120 includes a Helmholtz measuring coil 122 defining a passageway dimensioned so that the magnetized PCD sample 104 may be positioned therein on a sample holder 124. Once positioned in the passageway, the sample holder 124 supporting the magnetized PCD sample 104 may be moved axially along an axis direction 126 to induce a current in the Helmholtz measuring coil 122. Measurement electronics 128 are coupled to the Helmholtz measuring coil 122 and configured to calculate the magnetic saturation based upon the measured current passing through the Helmholtz measuring coil 122. The measurement electronics 128 may also be configured to calculate a weight percentage of magnetic material in the PCD sample 104 when the composition and magnetic characteristics of the metal-solvent catalyst in the PCD sample 104 are known, such as with iron, nickel, cobalt, and alloys thereof. Specific magnetic saturation may be calculated based upon the calculated magnetic saturation and the measured weight of the PCD sample 104.

The amount of metal-solvent catalyst in the PCD sample 104 may be determined using a number of different analytical techniques. For example, energy dispersive spectroscopy (e.g., EDAX), wavelength dispersive x-ray spectroscopy (e.g., WDX), Rutherford backscattering spectroscopy, or combinations thereof may be employed to determine the amount of metal-solvent catalyst in the PCD sample 104.

If desired, a specific magnetic saturation constant of the metal-solvent catalyst content in the PCD sample 104 may be determined using an iterative approach. A value for the specific magnetic saturation constant of the metal-solvent catalyst in the PCD sample 104 may be iteratively chosen until a metal-solvent catalyst content calculated by the analysis software of the KOERZIMAT CS 1.096 instrument using the chosen value substantially matches the metal-solvent catalyst content determined via one or more analytical techniques, such as energy dispersive spectroscopy, wavelength dispersive x-ray spectroscopy, or Rutherford backscattering spectroscopy.

FIG. 2 is a schematic diagram of a coercivity measurement apparatus 200 configured to determine a coercivity of a PCD sample. The coercivity measurement apparatus 200 includes a coil 202 and measurement electronics 204 coupled to the coil 202. The measurement electronics 204 are configured to pass a current through the coil 202 so that a magnetic field is generated. A sample holder 206 having a PCD sample 208 thereon may be positioned within the coil 202. A magnetization sensor 210 configured to measure a magnetization of the PCD sample 208 may be coupled to the measurement electronics 204 and positioned in proximity to the PCD sample 208.

During testing, the magnetic field generated by the coil 202 magnetizes the PCD sample 208 at least approximately to saturation. Then, the measurement electronics 204 apply a current so that the magnetic field generated by the coil 202 is increasingly reversed. The magnetization sensor 210 measures a magnetization of the PCD sample 208 resulting from application of the reversed magnetic field to the PCD sample 208. The measurement electronics 204 determine the coercivity of the PCD sample 208, which is a measurement of the strength of the reversed magnetic field at which the magnetization of the PCD sample 208 is zero.

Embodiments of Methods for Fabricating PCD

The PCD may be formed by sintering a mass of a plurality of diamond particles in the presence of a metal-solvent catalyst. The diamond particles may exhibit an average particle size of about 50 μm or less, such as about 30 μm or less, about 20 μm or less, about 10 μm to about 18 μm or, about 15 μm to about 18 μm. In some embodiments, the average particle size of the diamond particles may be about 10 μm or less, such as about 2 μm to about 5 μm or submicron.

In an embodiment, the diamond particles of the mass of diamond particles may comprise a relatively larger size and at least one relatively smaller size. As used herein, the phrases “relatively larger” and “relatively smaller” refer to particle sizes (by any suitable method) that differ by at least a factor of two (e.g., 30 μm and 15 μm). According to various embodiments, the mass of diamond particles may include a portion exhibiting a relatively larger size (e.g., 30 μm, 20 μm, 15 μm, 12 μm, 10 μm, 8 μm) and another portion exhibiting at least one relatively smaller size (e.g., 6 μm, 5 μm, 4 μm, 3 μm, 2 μm, 1 μm, 0.5 μm, less than 0.5 μm, 0.1 μm, less than 0.1 μm). In one embodiment, the mass of diamond particles may include a portion exhibiting a relatively larger size between about 10 μm and about 40 μm and another portion exhibiting a relatively smaller size between about 1 μm and 4 μm. In some embodiments, the mass of diamond particles may comprise three or more different sizes (e.g., one relatively larger size and two or more relatively smaller sizes), without limitation.

It is noted that the as-sintered diamond grain size may differ from the average particle size of the mass of diamond particles prior to sintering due to a variety of different physical processes, such as grain growth, diamond particle fracturing, carbon provided from another carbon source (e.g., dissolved carbon in the metal-solvent catalyst), or combinations of the foregoing. The metal-solvent catalyst (e.g., iron, nickel, cobalt, or alloys thereof) may be provided in particulate form mixed with the diamond particles, as a thin foil or plate placed adjacent to the mass of diamond particles, from a cemented carbide substrate including a metal-solvent catalyst, or combinations of the foregoing.

In order to efficiently sinter the mass of diamond particles, the mass may be enclosed in a pressure transmitting medium, such as a refractory metal can, graphite structure, pyrophyllite, combinations thereof, or other suitable pressure transmitting structure to form a cell assembly. Examples of suitable gasket materials and cell structures for use in manufacturing PCD are disclosed in U.S. Pat. No. 6,338,754 and U.S. patent application Ser. No. 11/545,929, each of which is incorporated herein, in its entirety, by this reference. Another example of a suitable pressure transmitting material is pyrophyllite, which is commercially available from Wonderstone Ltd. of South Africa. The cell assembly, including the pressure transmitting medium and mass of diamond particles therein, is subjected to an HPHT process using an ultra-high pressure press at a temperature of at least about 1000° C. (e.g., about 1100° C. to about 2200° C., or about 1200° C. to about 1450° C.) and a pressure in the pressure transmitting medium of at least about 7.5 GPa (e.g., about 7.5 GPa to about 15 GPa, about 9 GPa to about 12 GPa, or about 10 GPa to about 12.5 GPa) for a time sufficient to sinter the diamond particles together in the presence of the metal-solvent catalyst and form the PCD comprising bonded diamond grains defining interstitial regions occupied by the metal-solvent catalyst. For example, the pressure in the pressure transmitting medium employed in the HPHT process may be at least about 8.0 GPa, at least about 9.0 GPa, at least about 10.0 GPa, at least about 11.0 GPa, at least about 12.0 GPa, or at least about 14 GPa.

The pressure values employed in the HPHT processes disclosed herein refer to the pressure in the pressure transmitting medium at room temperature (e.g., about 25° C.) with application of pressure using an ultra-high pressure press and not the pressure applied to exterior of the cell assembly. The actual pressure in the pressure transmitting medium at sintering temperature may be slightly higher. The ultra-high pressure press may be calibrated at room temperature by embedding at least one calibration material that changes structure at a known pressure such as, PbTe, thallium, barium, or bismuth in the pressure transmitting medium. Optionally, a change in resistance may be measured across the at least one calibration material due to a phase change thereof. For example, PbTe exhibits a phase change at room temperature at about 6.0 GPa and bismuth exhibits a phase change at room temperature at about 7.7 GPa. Examples of suitable pressure calibration techniques are disclosed in G. Rousse, S. Klotz, A. M. Saitta, J. Rodriguez-Carvajal, M. I. McMahon, B. Couzinet, and M. Mezouar, “Structure of the Intermediate Phase of PbTe at High Pressure,” Physical Review B: Condensed Matter and Materials Physics, 71, 224116 (2005) and D. L. Decker, W. A. Bassett, L. Merrill, H. T. Hall, and J. D. Barnett, “High-Pressure Calibration: A Critical Review,” J. Phys. Chem. Ref. Data, 1, 3 (1972).

In an embodiment, a pressure of at least about 7.5 GPa in the pressure transmitting medium may be generated by applying pressure to a cubic high-pressure cell assembly that encloses the mass of diamond particles to be sintered using anvils, with each anvil applying pressure to a different face of the cubic high-pressure assembly. In such an embodiment, a surface area of each anvil face of the anvils may be selectively dimensioned to facilitate application of pressure of at least about 7.5 GPa to the mass of diamond particles being sintered. For example, the surface area of each anvil may be less than about 16.0 cm², such as less than about 16.0 cm², about 8 cm² to about 10 cm². The anvils may be made from a cobalt-cemented tungsten carbide or other material having a sufficient compressive strength to help reduce damage thereto through repetitive use in a high-volume commercial manufacturing environment. As an alternative to or in addition to selectively dimensioning the surface area of each anvil face, in an embodiment, two or more internal anvils may be embedded in the cubic high-pressure cell assembly to further intensify pressure. For example, the article W. Utsumi, N. Toyama, S. Endo and F. E. Fujita, “X-ray diffraction under ultrahigh pressure generated with sintered diamond anvils,” J. Appl. Phys., 60, 2201 (1986) is incorporated herein, in its entirety, by this reference and discloses that sintered diamond anvils may be embedded in a cubic pressure transmitting medium for intensifying the pressure applied by an ultra-high pressure press to a workpiece also embedded in the cubic pressure transmitting medium.

PDC Embodiments and Methods of Fabricating PDCs

Referring to FIG. 3A, the PCD embodiments may be employed in a PDC for cutting applications, bearing applications, or many other applications. FIG. 3A is a cross-sectional view of an embodiment of a PDC 300. The PDC 300 includes a substrate 302 bonded to a PCD table 304. The PCD table 304 may be formed of PCD in accordance with any of the PCD embodiments disclosed herein. The PCD table 304 exhibits at least one working surface 306 and at least one lateral dimension “D” (e.g., a diameter). Although FIG. 3A shows the working surface 306 as substantially planar, the working surface 306 may be concave, convex, or another nonplanar geometry. Furthermore, other regions of the PCD table 304 may function as a working region, such as a peripheral side surface and/or an edge. The substrate 302 may be generally cylindrical or another selected configuration, without limitation. Although FIG. 3A shows an interfacial surface 308 of the substrate 302 as being substantially planar, the interfacial surface 308 may exhibit a selected nonplanar topography, such as a grooved, ridged, or other nonplanar interfacial surface. The substrate 302 may include, without limitation, cemented carbides, such as tungsten carbide, titanium carbide, chromium carbide, niobium carbide, tantalum carbide, vanadium carbide, or combinations thereof cemented with iron, nickel, cobalt, or alloys thereof. For example, in one embodiment, the substrate 302 comprises cobalt-cemented tungsten carbide.

In some embodiments, the PCD table 304 may include two or more layered regions 310 and 312 exhibiting different compositions and/or different average diamond grain sizes. For example, the region 310 is located adjacent to the interface surface 308 of the substrate 302 and exhibits a first diamond grain size, while the region 312 is remote from the substrate 302 and exhibits a second average diamond grain size that is less than that of the first average diamond grain size. For example, the second average diamond grain size may be about 90% to about 98% (e.g., about 90 to about 95%) of the first diamond grain size. In another embodiment, the second average diamond grain size may be greater than that of the first average diamond grain size. For example, the first average diamond grain size may be about 90% to about 98% (e.g., about 90 to about 95%) of the second diamond grain size.

As an alternative to or in addition to the first and second regions exhibiting different diamond grain sizes, in an embodiment, the composition of the region 310 may be different than that of the region 312. The region 310 may include about 15 wt % or less of a tungsten-containing material (e.g., tungsten and/or tungsten carbide) interspersed between the diamond grains to improve toughness, while the region 312 may be substantially free of tungsten. For example, the tungsten-containing material may be present in the region 310 in an amount of about 1 wt % to about 10 wt %, about 5 wt % to about 10 wt %, or about 10 wt %.

FIG. 3B is a schematic illustration of an embodiment of a method for fabricating the PDC 300 shown in FIG. 3A. Referring to FIG. 3B, a mass of diamond particles 305 having any of the above-mentioned average particle sizes and distributions (e.g., an average particle size of about 50 μm or less) is positioned adjacent to the interfacial surface 308 of the substrate 302. As previously discussed, the substrate 302 may include a metal-solvent catalyst. The mass of diamond particles 305 and substrate 302 may be subjected to an HPHT process using any of the conditions previously described with respect to sintering the PCD embodiments disclosed herein. The PDC 300 so-formed includes the PCD table 304 that comprises PCD, formed of any of the PCD embodiments disclosed herein, integrally formed with the substrate 302 and bonded to the interfacial surface 308 of the substrate 302. If the substrate 302 includes a metal-solvent catalyst, the metal-solvent catalyst may liquefy and infiltrate the mass of diamond particles 305 to promote growth between adjacent diamond particles of the mass of diamond particles 305 to form the PCD table 304 comprised of a body of bonded diamond grains having the infiltrated metal-solvent catalyst interstitially disposed between bonded diamond grains. For example, if the substrate 302 is a cobalt-cemented tungsten carbide substrate, cobalt from the substrate 302 may be liquefied and infiltrate the mass of diamond particles 305 to catalyze formation of the PCD table 304.

In some embodiments, the mass of diamond particles 305 may include two or more layers exhibiting different compositions and/or different average diamond particle sizes. For example, a first layer may be located adjacent to the interface surface 308 of the substrate 302 and exhibit a first diamond particle size, while a second layer may be located remote from the substrate 302 and exhibit a second average diamond particle size that is less than that of the first average diamond particle size. For example, the second average diamond particle size may be about 90% to about 98% (e.g., about 90 to about 95%) of the first diamond particle size. In another embodiment, the second average diamond particle size may be greater than that of the first average diamond particle size. For example, the first average diamond particle size may be about 90% to about 98% (e.g., about 90 to about 95%) of the second diamond particle size.

As an alternative to or in addition to the first and second layers exhibiting different diamond particles sizes, in an embodiment, the composition of the first layer may be different than that of the second layer. The first layer may include about 15 wt % or less of a tungsten-containing material (e.g., tungsten and/or tungsten carbide) mixed with the diamond particles, while the second layer may be substantially free of tungsten. For example, the tungsten-containing material may be present in the first layer in an amount of about 1 wt % to about 10 wt %, about 5 wt % to about 10 wt %, or about 10 wt %.

Employing selectively dimensioned anvil faces and/or internal anvils in the ultra-high pressure press used to process the mass of diamond particles 305 and substrate 302 enables forming the at least one lateral dimension d of the PCD table 304 to be about 0.80 cm or more. Referring again to FIG. 3A, for example, the at least one lateral dimension “D” may be about 0.80 cm to about 3.0 cm and, in some embodiments, about 1.3 cm to about 1.9 cm or about 1.6 cm to about 1.9 cm. A representative volume of the PCD table 304 (or any PCD article of manufacture disclosed herein) formed using the selectively dimensioned anvil faces and/or internal anvils may be at least about 0.050 cm³. For example, the volume may be about 0.25 cm³ to at least about 1.25 cm³ or about 0.1 cm³ to at least about 0.70 cm³. A representative volume for the PDC 300 may be about 0.4 cm³ to at least about 4.6 cm³, such as about 1.1 cm³ to at least about 2.3 cm³.

In other embodiments, a PCD table according to an embodiment may be separately formed using an HPHT sintering process (i.e., a pre-sintered PCD table) and, subsequently, bonded to the interfacial surface 308 of the substrate 302 by brazing, using a separate HPHT bonding process, or any other suitable joining technique, without limitation. In yet another embodiment, a substrate may be formed by depositing a binderless carbide (e.g., tungsten carbide) via chemical vapor deposition onto the separately formed PCD table.

In any of the embodiments disclosed herein, substantially all or a selected portion of the metal-solvent catalyst may be removed (e.g., via leaching) from the PCD table. In an embodiment, metal-solvent catalyst in the PCD table may be removed to a selected depth from at least one exterior working surface (e.g., the working surface 306 and/or a sidewall working surface of the PCD table 304) so that only a portion of the interstitial regions are occupied by metal-solvent catalyst. For example, substantially all or a selected portion of the metal-solvent catalyst may be removed from the PCD table 304 of the PDC 300 to a selected depth from the working surface 306.

In another embodiment, a PCD table may be fabricated according to any of the disclosed embodiments in a first HPHT process, leached to remove substantially all of the metal-solvent catalyst from the interstitial regions between the bonded diamond grains, and subsequently bonded to a substrate in a second HPHT process. In the second HPHT process, an infiltrant from, for example, a cemented carbide substrate may infiltrate into the interstitial regions from which the metal-solvent catalyst was depleted. For example, the infiltrant may be cobalt that is swept-in from a cobalt-cemented tungsten carbide substrate. In one embodiment, the first and/or second HPHT process may be performed at a pressure of at least about 7.5 GPa. In one embodiment, the infiltrant may be leached from the infiltrated PCD table using a second acid leaching process following the second HPHT process.

In some embodiments, the pressure employed in the HPHT process used to fabricate the PDC 300 may be sufficient to reduce residual stresses in the PCD table 304 that develop during the HPHT process due to the thermal expansion mismatch between the substrate 302 and the PCD table 304. In such an embodiment, the principal stress measured on the working surface 306 of the PDC 300 may exhibit a value of about −345 MPa to about 0 MPa, such as about −289 MPa. For example, the principal stress measured on the working surface 306 may exhibit a value of about −345 MPa to about 0 MPa. A conventional PDC fabricated using an HPHT process at a pressure below about 7.5 GPa may result in a PCD table thereof exhibiting a principal stress on a working surface thereof of about −1724 MPa to about −414 MPa, such as about −770 MPa.

Residual stress may be measured on the working surface 306 of the PCD table 304 of the PDC 300 as described in T. P. Lin, M. Hood, G. A. Cooper, and R. H. Smith, “Residual stresses in polycrystalline diamond compacts,” J. Am. Ceram. Soc. 77, 6, 1562-1568 (1994). More particularly, residual strain may be measured with a rosette strain gage bonded to the working surface 306. Such strain may be measured for different levels of removal of the substrate 302 (e.g., as material is removed from the back of the substrate 302). Residual stress may be calculated from the measured residual strain data.

FIG. 3C is a graph of residual principal stress versus substrate thickness that was measured in a PCD table of a PDC fabricated at pressure above about 7.5 GPa in accordance with an embodiment of the invention and a PCD table of a conventionally formed PDC. The substrate of each PDC had a substantially planar interfacial surface. The residual principal stress was determined using the technique described in the article referenced above by Lin et al. Curve 310 shows the measured residual principal stress on a working surface of the PDC fabricated at a pressure above about 7.5 GPa. The PDC that was fabricated at a pressure above about 7.5 GPa had a PCD table thickness dimension of about 1 mm and the substrate had a thickness dimension of about 7 mm and a diameter of about 13 mm. Curve 312 shows the measured residual principal stress on a working surface of a PCD table of a conventionally PDC fabricated at pressure below about 7.5 GPa. The PDC that was fabricated at a pressure below about 7.5 GPa had a PCD table thickness dimension of about 1 mm and the substrate had a thickness dimension of about 7 mm and a diameter of about 13 mm. The highest absolute value of the residual principal stress occurs with the full substrate length of about 7 mm. As shown by the curves 310 and 312, increasing the pressure employed in the HPHT process used to fabricate a PDC, above about 7.5 GPa may reduce the highest absolute value of the principal residual stress in a PCD table thereof by about 60% relative to a conventionally fabricated PDC. For example, at the full substrate length, the absolute value of the principal residual stress in the PCD table fabricated at a pressure above about 7.5 GPa is about 60% less than the absolute value of the principal residual stress in the PCD table of the conventionally fabricated PDC.

As discussed above in relation to FIG. 3C, the application of higher pressure in the HPHT process used to fabricate a PDC may substantially reduce the residual compressive stresses in the PCD table. Typically, high residual compressive stresses in the PCD table are believed desirable to help reduce crack propagation in the PCD table. The inventors have found that the reduced residual compressive stresses in a PCD table of a PDC fabricated in an HPHT process at a pressure of at least about 7.5 GPa may result in detrimental cracking in the PCD table and de-bonding of the PCD table from the substrate upon brazing the substrate to, for example, a carbide extension and/or a bit body of a rotary drill bit depending upon the extent of the nonplanarity of the interfacial surface of the substrate. It is believed by the inventors that when the PDC is fabricated at a pressure of at least about 7.5 GPa, at the brazing temperature, tensile stresses generated in the PCD table due to thermal expansion are greater than if the PCD table had higher residual compressive stresses. Due to the higher tensile stresses at the brazing temperature, hoop stresses generated in the PCD by nonplanar surface features (e.g., protrusions) of the substrate may cause the PCD table to form radially-extending and vertically-extending cracks and/or de-bond from the substrate more frequently than if fabricated at relatively lower pressures. Typically, conventional wisdom taught that a highly nonplanar interfacial surface for the substrate helped prevent de-bonding of the PCD table from the substrate. Thus, in certain embodiments discussed in more detail in FIGS. 3A-6B, the inventors have proceeded contrary to conventional wisdom, which suggested that a highly nonplanar interfacial surface for the substrate promotes bonding. In such embodiments, the topography of the interfacial surface of the substrate may be controlled so that it is still substantially planar and exhibits a nonplanarity that does not exceed a maximum threshold.

Referring again to FIG. 3A, in an embodiment, the interfacial surface 308 of the substrate 302 may be substantially planar. For example, to the extent that the interfacial surface 308 includes a plurality of protrusions, the protrusions may exhibit an average surface relief height of about 0 to less than about 0.00010 inch, about 0 to about 0.00050 inch, about 0 to about 0.00075 inch, or about 0.000010 inch to about 0.00010 inch. The average surface relief is the height that the protrusions extend above the lowest point of the interfacial surface 308. A ratio of a surface area of the interfacial surface in the absence of the plurality of protrusions (i.e., a flat interfacial surface) to a surface area of the interfacial surface with the plurality of protrusions is greater than about 0.600. An example of an interfacial surface that is substantially planar is one in which the ratio is greater than about 0.600. For example, the ratio may be about 0.600 to about 0.650, about 0.650 to about 0.725, about 0.650 to about 0.750, about 0.650 to about 0.950, about 0.750 to less than 1.0, or about 0.750 to about 1.0.

FIGS. 4A-6B illustrate embodiments in which the selected substantially planar topography of the interfacial surface of the substrate is controlled to reduce or substantially eliminate cracking in and/or de-bonding of a PCD table of a PDC. FIGS. 4A and 4B are exploded isometric and assembled isometric views, respectively, of an embodiment of a PDC 400 comprising a substrate 402 including an interfacial surface 404 exhibiting a selected substantially planar topography. The substrate 402 may be made from the same carbide materials as the substrate 302 shown in FIG. 3A. The interfacial surface 404 includes a plurality of protrusions 406 spaced from each other and extending substantially transversely to the length of the substrate 402. The protrusions 406 define a plurality of grooves 408 between pairs of the protrusions 406. A PCD table 410 may be bonded to the interfacial surface 406. The PCD table 410 may exhibit some or all of the magnetic, mechanical, thermal stability, wear resistance, size, compositional, diamond-to-diamond bonding, or grain size properties of the PCD disclosed herein and/or the PCD table 304 shown in FIG. 3A. The PCD table 410 exhibits a maximum thickness “T.” Because the PCD table 410 may be integrally formed with the substrate 402 and fabricated from precursor diamond particles, the PCD table 410 may have an interfacial surface 411 that is configured to correspond to the topography of the interfacial surface 404 of the substrate 402.

A ratio of a surface area of the interfacial surface 404 in the absence of the plurality of protrusions 406 (i.e., a flat interfacial surface) to a surface area of the interfacial surface with the protrusions 406 is greater than about 0.600. For example, the ratio may be about 0.600 to about 0.650, about 0.650 to about 0.725, about 0.650 to about 0.750, about 0.650 to about 0.950, about 0.750 to less than 1.0, or about 0.750 to about 1.0.

The plurality of protrusions 406 exhibits an average surface relief height “h,” which is the average height that the protrusions 406 extend above the lowest point of the interfacial surface 404. For example, h may be greater than 0 to less than about 0.030 inch, greater than 0 to about 0.020 inch, greater than 0 to about 0.015 inch, about 0.0050 inch to about 0.010 inch, or 0.0080 inch to about 0.010 inch. The maximum thickness “T” may be about 0.050 inch to about 0.20 inch, such as about 0.050 inch to about 0.16 inch, about 0.050 inch to about 0.10 inch, about 0.050 inch to about 0.085 inch or about 0.070 inch to about 0.080 inch. The ratio of h/T may be less than about 0.25, such as about 0.050 to about 0.125, about 0.050 to about 0.10, about 0.070 to about 0.090, or about 0.050 to about 0.075.

Referring to FIG. 4B, the outermost of the protrusions 406 (indicated as 406 a and 406 b) may be laterally spaced from an exterior peripheral surface 414 of the substrate 402 by a distance d. When the PDC 400 is substantially cylindrical, a ratio of d to the radius of the PCD table “R” may be about 0.030 to about 1.0, about 0.035 to about 0.080, or about 0.038 to about 0.060.

FIG. 5A is cross-sectional view of a PDC 500 comprising a substrate 502 including an interfacial surface 504 exhibiting a selected substantially planar topography according to yet another embodiment and FIG. 5B is an isometric view of the substrate 502. The substrate 502 may be made from the same carbide materials as the substrate 302 shown in FIG. 3A. The interfacial surface 504 of the substrate 502 includes a plurality of hexagonal protrusions 506 that extend outwardly from a face 508. The face 508 may be convex, as in the illustrated embodiment, or substantially planar. Tops 509 of the protrusions 506 may lie generally in a common plane. The plurality of protrusions 506 defines a plurality of internal cavities 510. A depth of each internal cavity 510 may decrease as they approach the center of the substrate 502. A bottom 511 of each cavity 510 may follow the profile of the face 508.

The PDC 500 further includes a PCD table 512 exhibiting a maximum thickness “T,” which is bonded to the interfacial surface 504 of the substrate 502. The thickness of the PCD table 512 gradually increases with lateral distance from the center of the PCD table 512 toward a perimeter 513 of the PDC 500. The PCD table 512 may be configured to correspond to the topography of the interfacial surface 504 of the substrate 502. For example, protrusions 513 of the PCD table 512 may fill each of the internal cavities 510 defined by the protrusions 506 of the substrate 502. The PCD table 512 may exhibit some or all of the magnetic, mechanical, thermal stability, wear resistance, size, compositional, diamond-to-diamond bonding, or grain size properties of the PCD disclosed herein and/or the PCD table 304 shown in FIG. 3A. The closed features of the hexagonal protrusions 506 include a draft angle α, such as about 5 degrees to about 15 degrees.

A ratio of a surface area of the interfacial surface 504 in the absence of the protrusions 506 (i.e., a flat interfacial surface) to a surface area of the interfacial surface with the protrusions 506 is greater than about 0.600. For example, the ratio may be about 0.600 to about 0.650, about 0.650 to about 0.725, about 0.650 to about 0.750, about 0.650 to about 0.950, about 0.750 to less than 1.0, or about 0.750 to about 1.0.

The plurality of protrusions 506 exhibits an average surface relief height “h,” which is the average height that the protrusions 506 extend above the lowest point of the interfacial surface 504. For example, h may be greater than 0 to less than about 0.030 inch, greater than 0 to about 0.020 inch, greater than 0 to about 0.015 inch, about 0.0050 inch to about 0.010 inch, or 0.0080 inch to about 0.010 inch. The maximum thickness “T” may be about 0.050 inch to about 0.10 inch, such as about 0.050 inch to about 0.085 inch or about 0.070 inch to about 0.080 inch. The ratio of h/T may be less than about 0.25, such as about 0.050 to about 0.125, about 0.050 to about 0.10, about 0.070 to about 0.090, or about 0.050 to about 0.075.

It is noted that the interfacial surface geometries shown in the PDCs 400 and 500 are merely two examples of suitable interfacial surface geometries. Other interfacial surface geometries may be employed that depart from the illustrated interfacial surface geometries shown in the PDCs 400 and 500 of FIGS. 4A-5B.

Working Examples

The following working examples provide further detail about the magnetic properties of PCD tables of PDCs fabricated in accordance with the principles of some of the specific embodiments of the invention. The magnetic properties of each PCD table listed in Tables I-IV were tested using a KOERZIMAT CS 1.096 instrument that is commercially available from Foerster Instruments of Pittsburgh, Pa. The specific magnetic saturation of each PCD table was measured in accordance with ASTM B886-03 (2008) and the coercivity of each PCD table was measured using ASTM B887-03 (2008) e1 using a KOERZIMAT CS 1.096 instrument. The amount of cobalt-based metal-solvent catalyst in the tested PCD tables was determined using energy dispersive spectroscopy and Rutherford backscattering spectroscopy. The specific magnetic saturation constant of the cobalt-based metal-solvent catalyst in the tested PCD tables was determined to be about 201 G·cm³/g using an iterative analysis as previously described. When a value of 201 G·cm³/g was used for the specific magnetic saturation constant of the cobalt-based metal-solvent catalyst, the calculated amount of the cobalt-based metal-solvent catalyst in the tested PCD tables using the analysis software of the KOERZIMAT CS 1.096 instrument substantially matched the measurements using energy dispersive spectroscopy and Rutherford spectroscopy.

Table I below lists PCD tables that were fabricated in accordance with the principles of certain embodiments of the invention discussed above. Each PCD table was fabricated by placing a mass of diamond particles having the listed average diamond particle size adjacent to a cobalt-cemented tungsten carbide substrate in a niobium container, placing the container in a high-pressure cell medium, and subjecting the high-pressure cell medium and the container therein to an HPHT process using an HPHT cubic press to form a PCD table bonded to the substrate. The surface area of each anvil of the HPHT press and the hydraulic line pressure used to drive the anvils were selected so that the sintering pressure was at least about 7.8 GPa. The temperature of the HPHT process was about 1400° C. and the sintering pressure was at least about 7.8 GPa. The sintering pressures listed in Table I refer to the pressure in the high-pressure cell medium at room temperature, and the actual sintering pressures at the sintering temperature are believed to be greater. After the HPHT process, the PCD table was removed from the substrate by grinding away the substrate. However, the substrate may also be removed using electro-discharge machining or another suitable method.

TABLE I Selected Magnetic Properties of PCD Tables Fabricated According to Embodiments of the Invention. Average Diamond Specific Specific Particle Sintering Magnetic Permeability Size Pressure Saturation Calculated Coercivity (G · cm³/ Example (μm) (GPa) (G · cm³/g) Co wt % (Oe) g · Oe) 1 20 7.8 11.15 5.549 130.2 0.08564 2 19 7.8 11.64 5.792 170.0 0.06847 3 19 7.8 11.85 5.899 157.9 0.07505 4 19 7.8 11.15 5.550 170.9 0.06524 5 19 7.8 11.43 5.689 163.6 0.06987 6 19 7.8 10.67 5.150 146.9 0.07263 7 19 7.8 10.76 5.357 152.3 0.07065 8 19 7.8 10.22 5.087 145.2 0.07039 9 19 7.8 10.12 5.041 156.6 0.06462 10 19 7.8 10.72 5.549 137.1 0.07819 11 11 7.8 12.52 6.229 135.3 0.09254 12 11 7.8 12.78 6.362 130.5 0.09793 13 11 7.8 12.69 6.315 134.6 0.09428 14 11 7.8 13.20 6.569 131.6 0.1003

Table II below lists conventional PCD tables that were fabricated. Each PCD table listed in Table II was fabricated by placing a mass of diamond particles having the listed average diamond particle size adjacent to a cobalt-cemented tungsten carbide substrate in a niobium container, placing container in a high-pressure cell medium, and subjecting the high-pressure cell medium and the container therein to an HPHT process using an HPHT cubic press to form a PCD table bonded to the substrate. The surface area of each anvil of the HPHT press and the hydraulic line pressure used to drive the anvils were selected so that the sintering pressure was about 4.6 GPa. Except for samples 15, 16, 18, and 19, which were subjected to a temperature of about 1430° C., the temperature of the HPHT process was about 1400° C. and the sintering pressure was about 4.6 GPa. The sintering pressures listed in Table II refer to the pressure in the high-pressure cell medium at room temperature. After the HPHT process, the PCD table was removed from the cobalt-cemented tungsten carbide substrate by grinding away the cobalt-cemented tungsten carbide substrate.

TABLE II Selected Magnetic Properties of Several Conventional PCD Tables. Average Diamond Specific Specific Particle Sintering Magnetic Permeability Size Pressure Saturation Calculated Coercivity (G · cm³/ Example (μm) (GPa) (G · cm³/g) Co wt % (Oe) g · Oe) 15 20 4.61 19.30 9.605 94.64 0.2039 16 20 4.61 19.52 9.712 96.75 0.2018 17 20 4.61 19.87 9.889 94.60 0.2100 18 20 5.08 18.61 9.260 94.94 0.1960 19 20 5.08 18.21 9.061 100.4 0.1814 20 20 5.86 16.97 8.452 108.3 0.1567 21 20 4.61 17.17 8.543 102.0 0.1683 22 20 4.61 17.57 8.745 104.9 0.1675 23 20 5.08 16.10 8.014 111.2 0.1448 24 20 5.08 16.79 8.357 107.1 0.1568

As shown in Tables I and II, the conventional PCD tables listed in Table II exhibit a higher cobalt content therein than the PCD tables listed in Table I as indicated by the relatively higher specific magnetic saturation values. Additionally, the conventional PCD tables listed in Table II exhibit a lower coercivity indicative of a relatively greater mean free path between diamond grains, and thus may indicate relatively less diamond-to-diamond bonding between the diamond grains. Thus, the PCD tables according to examples of the invention listed in Table I may exhibit significantly less cobalt therein and a lower mean free path between diamond grains than the PCD tables listed in Table II.

Table III below lists conventional PCD tables that were obtained from PDCs. Each PCD table listed in Table III was separated from a cobalt-cemented tungsten carbide substrate bonded thereto by grinding.

TABLE III Selected Magnetic Properties of Several Conventional PCD Tables. Specific Magnetic Specific Saturation Calculated Coercivity Permeability Example (G · cm³/g) Co wt % (Oe) (G · cm³/g · Oe) 25 17.23 8.572 140.4 0.1227 26 16.06 7.991 150.2 0.1069 27 15.19 7.560 146.1 0.1040 28 17.30 8.610 143.2 0.1208 29 17.13 8.523 152.1 0.1126 30 17.00 8.458 142.5 0.1193 31 17.08 8.498 147.2 0.1160 32 16.10 8.011 144.1 0.1117

Table IV below lists conventional PCD tables that were obtained from PDCs. Each PCD table listed in Table IV was separated from a cobalt-cemented tungsten carbide substrate bonded thereto by grinding the substrate away. Each PCD table listed in Table IV and tested had a leached region from which cobalt was depleted and an unleached region in which cobalt is interstitially disposed between bonded diamond grains. The leached region was not removed. However, to determine the specific magnetic saturation and the coercivity of the unleached region of the PCD table having metal-solvent catalyst occupying interstitial regions therein, the leached region may be ground away so that only the unleached region of the PCD table remains. It is expected that the leached region causes the specific magnetic saturation to be lower and the coercivity to be higher than if the leached region was removed and the unleached region was tested.

TABLE IV Selected Magnetic Properties of Several Conventional Leached PCD Tables. Specific Magnetic Specific Saturation Calculated Coercivity Permeability Example (G · cm³ per gram) Co wt % (Oe) (G · cm³ per g · Oe) 33 17.12 8.471 143.8 0.1191  34 13.62 6.777 137.3 0.09920 35 15.87 7.897 140.1 0.1133  36 12.95 6.443 145.5 0.0890  37 13.89 6.914 142.0 0.09782 38 13.96 6.946 146.9 0.09503 39 13.67 6.863 133.8 0.1022  40 12.80 6.369 146.3 0.08749

As shown in Tables I, III, and IV, the conventional PCD tables of Tables III and IV exhibit a higher cobalt content therein than the PCD tables listed in Table I as indicated by the relatively higher specific magnetic saturation values. This is believed by the inventors to be a result of the PCD tables listed in Tables III and IV being formed by sintering diamond particles having a relatively greater percentage of fine diamond particles than the diamond particle formulations used to fabricate the PCD tables listed in Table I.

Examples 41-120 tested four different substrate interfacial surface geometries to evaluate the effect of the interfacial surface area of the substrate. Twenty samples of each substrate interfacial surface geometry were tested. All of the PDCs in examples 41-120 were fabricated by placing a mass of diamond particles having an average diamond particle size of about 19 μm adjacent to a cobalt-cemented tungsten carbide substrate in a niobium container, placing the container in a high-pressure cell medium, and subjecting the high-pressure cell medium and the container therein to an HPHT process using an HPHT cubic press to form a PCD table bonded to the substrate. The surface area of each anvil of the HPHT press and the hydraulic line pressure used to drive the anvils were selected so that the sintering pressure was at least about 7.7 GPa. The temperature of the HPHT process was about 1400° C. The sintering pressure of 7.7 GPa refers to the pressure in the high-pressure cell medium at room temperature, and the actual sintering pressure at the sintering temperature of about 1400° C. is believed to be greater.

The interfacial surface for the substrate in the PDCs of examples 41-60 was a substantially planar interfacial surface having essentially no surface topography other than surface roughness. The interfacial surface for the substrate in the PDCs of examples 61-80 was similar to the interfacial surface 404 shown in FIG. 4A. The interfacial surface for the substrate in the PDCs of Examples 81-100 was slightly convex with a plurality of radially and circumferentially equally-spaced cylindrical protrusions. The interfacial surface for the substrate in the PDCs of examples 101-120 was similar to the interfacial surface 504 shown in FIGS. 5A and 5B.

After fabricating the PDC s of examples 41-120, the substrate of each PDC was brazed to an extension cobalt-cemented tungsten carbide substrate. The braze alloy had a composition of about 25 wt % Au, about 10 wt % Ni, about 15 wt % Pd, about 13 wt % Mn, and about 37 wt % Cu. The brazing process was performed at a brazing temperature of about 1013° C. After the brazing process, the PDCs of examples 41-120 were individually examined using an optical microscope to determine if cracks were present in the PCD tables.

Table V below lists the substrate diameter, surface area of the interfacial surface of the substrates for each type of substrate geometry, the ratio of the interfacial surface area of the substrate to a flat interfacial surface of a substrate with the same diameter, and the number of PDC samples in which the PCD table cracked upon brazing to the extension cobalt-cemented tungsten carbide substrate. As shown in Table V, as the surface area of the interfacial surface of the substrate decreases, the prevalence of the PCD table cracking decreases upon brazing.

TABLE V Effect of Substrate Interfacial Surface Area on PCD Table Cracking Upon Brazing Number of Interfacial Samples That Substrate Surface Area of Cracked When Example Diameter (in) Substrate (in²) Ratio Brazed 41-60 0.625 0.308 1.0  0 61-80 0.625 0.398 0.772 0  81-100 0.625 0.524 0.588 2 out of 20 101-120 0.625 0.585 0.526 9 out of 20

Embodiments of Applications for PCD and PDCs

The disclosed PCD and PDC embodiments may be used in a number of different applications including, but not limited to, use in a rotary drill bit (FIGS. 6A and 6B), a thrust-bearing apparatus (FIG. 7), a radial bearing apparatus (FIG. 8), a subterranean drilling system (FIG. 9), and a wire-drawing die (FIG. 10). The various applications discussed above are merely some examples of applications in which the PCD and PDC embodiments may be used. Other applications are contemplated, such as employing the disclosed PCD and PDC embodiments in friction stir welding tools.

FIG. 6A is an isometric view and FIG. 6B is a top elevation view of an embodiment of a rotary drill bit 600. The rotary drill bit 600 includes at least one PDC configured according to any of the previously described PDC embodiments. The rotary drill bit 600 comprises a bit body 602 that includes radially and longitudinally extending blades 604 with leading faces 606, and a threaded pin connection 608 for connecting the bit body 602 to a drilling string. The bit body 602 defines a leading end structure for drilling into a subterranean formation by rotation about a longitudinal axis 610 and application of weight-on-bit. At least one PDC cutting element, configured according to any of the previously described PDC embodiments (e.g., the PDC 300 shown in FIG. 3A), may be affixed to the bit body 602. With reference to FIG. 6B, a plurality of PDCs 612 are secured to the blades 604. For example, each PDC 612 may include a PCD table 614 bonded to a substrate 616. More generally, the PDCs 612 may comprise any PDC disclosed herein, without limitation. In addition, if desired, in some embodiments, a number of the PDCs 612 may be conventional in construction. Also, circumferentially adjacent blades 604 define so-called junk slots 618 therebetween, as known in the art. Additionally, the rotary drill bit 600 may include a plurality of nozzle cavities 620 for communicating drilling fluid from the interior of the rotary drill bit 600 to the PDCs 612.

FIGS. 6A and 6B merely depict an embodiment of a rotary drill bit that employs at least one cutting element comprising a PDC fabricated and structured in accordance with the disclosed embodiments, without limitation. The rotary drill bit 600 is used to represent any number of earth-boring tools or drilling tools, including, for example, core bits, roller-cone bits, fixed-cutter bits, eccentric bits, bicenter bits, reamers, reamer wings, or any other downhole tool including PDCs, without limitation.

The PCD and/or PDCs disclosed herein (e.g., the PDC 300 shown in FIG. 3A) may also be utilized in applications other than rotary drill bits. For example, the disclosed PDC embodiments may be used in thrust-bearing assemblies, radial bearing assemblies, wire-drawing dies, artificial joints, machining elements, and heat sinks.

FIG. 7 is an isometric cutaway view of an embodiment of a thrust-bearing apparatus 700, which may utilize any of the disclosed PDC embodiments as bearing elements. The thrust-bearing apparatus 700 includes respective thrust-bearing assemblies 702. Each thrust-bearing assembly 702 includes an annular support ring 704 that may be fabricated from a material, such as carbon steel, stainless steel, or another suitable material. Each support ring 704 includes a plurality of recesses (not labeled) that receive a corresponding bearing element 706. Each bearing element 706 may be mounted to a corresponding support ring 704 within a corresponding recess by brazing, press-fitting, using fasteners, or another suitable mounting technique. One or more, or all of bearing elements 706 may be configured according to any of the disclosed PDC embodiments. For example, each bearing element 706 may include a substrate 708 and a PCD table 710, with the PCD table 710 including a bearing surface 712.

In use, the bearing surfaces 712 of one of the thrust-bearing assemblies 702 bear against the opposing bearing surfaces 712 of the other one of the bearing assemblies 702. For example, one of the thrust-bearing assemblies 702 may be operably coupled to a shaft to rotate therewith and may be termed a “rotor.” The other one of the thrust-bearing assemblies 702 may be held stationary and may be termed a “stator.”

FIG. 8 is an isometric cutaway view of an embodiment of a radial bearing apparatus 800, which may utilize any of the disclosed PDC embodiments as bearing elements. The radial bearing apparatus 800 includes an inner race 802 positioned generally within an outer race 804. The outer race 804 includes a plurality of bearing elements 806 affixed thereto that have respective bearing surfaces 808. The inner race 802 also includes a plurality of bearing elements 810 affixed thereto that have respective bearing surfaces 812. One or more, or all of the bearing elements 806 and 810 may be configured according to any of the PDC embodiments disclosed herein. The inner race 802 is positioned generally within the outer race 804 and, thus, the inner race 802 and outer race 804 may be configured so that the bearing surfaces 808 and 812 may at least partially contact one another and move relative to each other as the inner race 802 and outer race 804 rotate relative to each other during use.

The radial bearing apparatus 800 may be employed in a variety of mechanical applications. For example, so-called “roller cone” rotary drill bits may benefit from a radial bearing apparatus disclosed herein. More specifically, the inner race 802 may be mounted to a spindle of a roller cone and the outer race 804 may be mounted to an inner bore formed within a cone and that such an outer race 804 and inner race 802 may be assembled to form a radial bearing apparatus.

Referring to FIG. 9, the thrust-bearing apparatus 700 and/or radial bearing apparatus 800 may be incorporated in a subterranean drilling system. FIG. 9 is a schematic isometric cutaway view of a subterranean drilling system 900 that includes at least one of the thrust-bearing apparatuses 700 shown in FIG. 7 according to another embodiment. The subterranean drilling system 900 includes a housing 902 enclosing a downhole drilling motor 904 (i.e., a motor, turbine, or any other device capable of rotating an output shaft) that is operably connected to an output shaft 906. A first thrust-bearing apparatus 700 ₁ (FIG. 7) is operably coupled to the downhole drilling motor 904. A second thrust-bearing apparatus 700 ₂ (FIG. 7) is operably coupled to the output shaft 906. A rotary drill bit 908 configured to engage a subterranean formation and drill a borehole is connected to the output shaft 906. The rotary drill bit 908 is shown as a roller cone bit including a plurality of roller cones 910. However, other embodiments may utilize different types of rotary drill bits, such as a so-called “fixed cutter” drill bit shown in FIGS. 6A and 6B. As the borehole is drilled, pipe sections may be connected to the subterranean drilling system 900 to form a drill string capable of progressively drilling the borehole to a greater depth within the earth.

A first one of the thrust-bearing assemblies 702 of the thrust-bearing apparatus 700 ₁ is configured as a stator that does not rotate and a second one of the thrust-bearing assemblies 702 of the thrust-bearing apparatus 700 ₁ is configured as a rotor that is attached to the output shaft 906 and rotates with the output shaft 906. The on-bottom thrust generated when the drill bit 908 engages the bottom of the borehole may be carried, at least in part, by the first thrust-bearing apparatus 700 ₁. A first one of the thrust-bearing assemblies 702 of the thrust-bearing apparatus 700 ₂ is configured as a stator that does not rotate and a second one of the thrust-bearing assemblies 702 of the thrust-bearing apparatus 700 ₂ is configured as a rotor that is attached to the output shaft 906 and rotates with the output shaft 906. Fluid flow through the power section of the downhole drilling motor 904 may cause what is commonly referred to as “off-bottom thrust,” which may be carried, at least in part, by the second thrust-bearing apparatus 700 ₂.

In operation, drilling fluid may be circulated through the downhole drilling motor 904 to generate torque and effect rotation of the output shaft 906 and the rotary drill bit 908 attached thereto so that a borehole may be drilled. A portion of the drilling fluid may also be used to lubricate opposing bearing surfaces of the bearing elements 706 of the thrust-bearing assemblies 702.

FIG. 10 is a side cross-sectional view of an embodiment of a wire-drawing die 1000 that employs a PDC 1002 fabricated in accordance with the teachings described herein. The PDC 1002 includes an inner, annular PCD region 1004 comprising any of the PCD tables described herein that is bonded to an outer cylindrical substrate 1006 that may be made from the same materials as the substrate 302 shown in FIG. 3A. The PCD region 1004 also includes a die cavity 1008 formed therethrough configured for receiving and shaping a wire being drawn. The wire-drawing die 1000 may be encased in a housing (e.g., a stainless steel housing), which is not shown, to allow for handling.

In use, a wire 1010 of a diameter d₁ is drawn through die cavity 1008 along a wire drawing axis 1012 to reduce the diameter of the wire 1010 to a reduced diameter d₂.

While various aspects and embodiments have been disclosed herein, other aspects and embodiments are contemplated. The various aspects and embodiments disclosed herein are for purposes of illustration and are not intended to be limiting. Additionally, the words “including,” “having,” and variants thereof (e.g., “includes” and “has”) as used herein, including the claims, shall have the same meaning as the word “comprising” and variants thereof (e.g., “comprise” and “comprises”). 

1. (canceled)
 2. A polycrystalline diamond compact, comprising: a polycrystalline diamond table, at least an unleached portion of the polycrystalline diamond table including: a plurality of diamond grains bonded together via diamond-to-diamond bonding to define a plurality of interstitial regions, the plurality of diamond grains exhibiting an average grain size of about 10 μm to about 50 μm; a catalyst occupying at least a portion of the plurality of interstitial regions; a catalyst content of the catalyst of about 1 weight % to about 7.5 weight %; and a coercivity greater than about 115 Oe to about 250 Oe.
 3. The polycrystalline diamond compact of claim 2, wherein the average grain size of the plurality of diamond grains is about 10 μm to about 30 μm.
 4. The polycrystalline diamond compact of claim 3, wherein the average grain size of the plurality of diamond grains is about 10 μm to about 18 μm.
 5. The polycrystalline diamond compact of claim 2, wherein the coercivity of the unleached portion of the polycrystalline diamond table is about 115 Oe to about 175 Oe.
 6. The polycrystalline diamond compact of claim 2, wherein the polycrystalline diamond table exhibits one or more characteristics of being sintered at a cell pressure of about 7.5 GPa to about 15 GPa.
 7. The polycrystalline diamond compact of claim 2, wherein the unleached portion of the polycrystalline diamond table exhibits a specific magnetic saturation of greater than 0 G·cm³/g to about 15 G·cm³/g.
 8. The polycrystalline diamond compact of claim 7, wherein the specific magnetic saturation of the unleached portion of the polycrystalline diamond table is about 10 G·cm³/g to about 15 G·cm³/g.
 9. The polycrystalline diamond compact of claim 8, wherein the unleached portion of the polycrystalline diamond table exhibits a specific permeability of less than about 0.10 G·cm³/g·Oe.
 10. The polycrystalline diamond compact of claim 9, wherein the specific permeability of the unleached portion of the polycrystalline diamond table is about 0.6 G·cm³/g·Oe to about 0.9 G·cm³/g·Oe.
 11. The polycrystalline diamond compact of claim 9, wherein the unleached portion of the polycrystalline diamond table exhibits a Gratin of at least about 4.0×10⁶.
 12. The polycrystalline diamond compact of claim 11, wherein the G_(ratio) of the unleached portion of the polycrystalline diamond table is about 5.0×10⁶ to about 15.0×10⁶.
 13. The polycrystalline diamond compact of claim 9, wherein the polycrystalline diamond table exhibits a thermal stability, as determined by a distance cut, prior to failure, in a vertical lathe test of about 1300 m to about 3950 m.
 14. A rotary drill bit, comprising: a bit body including a leading end structure configured to facilitate drilling a subterranean formation; and a plurality of cutting elements mounted to the bit body, at least one of the plurality of cutting elements including the polycrystalline diamond compact according to claim
 2. 15. A polycrystalline diamond compact, comprising: a polycrystalline diamond table, at least an unleached portion of the polycrystalline diamond table including: a plurality of diamond grains bonded together via diamond-to-diamond bonding to define interstitial regions, the plurality of diamond grains exhibiting an average grain size of about 10 μm to about 30 μm; a catalyst including cobalt, the catalyst occupying at least a portion of the interstitial regions; a catalyst content of the catalyst of about 1 weight % to about 7.5 weight %; a coercivity of about 115 Oe to about 250 Oe; and a specific magnetic saturation of about 5 G·cm³/g to about 15 G·cm³/g or less; and a substrate bonded to the polycrystalline diamond table along an interfacial surface.
 16. The polycrystalline diamond table of claim 15, wherein the unleached portion of the polycrystalline diamond table exhibits a G_(ratio) of at least about 4.0×10⁶.
 17. A rotary drill bit, comprising: a bit body including a leading end structure configured to facilitate drilling a subterranean formation; and a plurality of cutting elements mounted to the bit body, at least one of the plurality of cutting elements including the polycrystalline diamond compact according to claim
 15. 18. A polycrystalline diamond compact, comprising: a polycrystalline diamond table sintered exhibiting one or more characteristics of being sintered at a cell pressure of at least about 7.5 GPa, at least an unleached portion of the polycrystalline diamond table including: a plurality of diamond grains bonded together via diamond-to-diamond bonding to define interstitial regions, the plurality of diamond grains exhibiting an average grain size of about 10 μm to about 18 μm; a catalyst including cobalt, the catalyst occupying at least a portion of the interstitial regions; a catalyst content of the catalyst of about 3 weight % to about 7.5 weight %; a coercivity of about 115 Oe to about 175 Oe; a specific magnetic saturation of about 10 G·cm³/g to about 15 G·cm³/g; and a specific permeability of less than about 0.10 G·cm³/g·Oe; and a substrate bonded to the polycrystalline diamond table along an interfacial surface.
 19. The polycrystalline diamond table of claim 18, wherein the unleached portion of the polycrystalline diamond table exhibits a G_(ratio) of at least about 4.0×10⁶.
 20. The polycrystalline diamond compact of claim 18, wherein the specific permeability of the unleached portion of the polycrystalline diamond table is about 0.6 G·cm³/g·Oe to about 0.9 G·cm³/g·Oe.
 21. The polycrystalline diamond compact of claim 18, wherein the polycrystalline diamond table exhibits a thermal stability, as determined by a distance cut, prior to failure, in a vertical lathe test of at least about 1300 m.
 22. A rotary drill bit, comprising: a bit body including a leading end structure configured to facilitate drilling a subterranean formation; and a plurality of cutting elements mounted to the bit body, at least one of the plurality of cutting elements including the polycrystalline diamond compact according to claim
 18. 